DE1952697B2 - DEVICE FOR ELECTRONIC IGNITION OF GAS DISCHARGE LAMPS - Google Patents

Description

should be guaranteed in the long term. In addition, the ignition device should have small dimensions, so that in a replaceable housing, as is usual for starters, or in the fitting of the gas discharge lamp can be accommodated.

According to the invention this object is achieved in a
Ignition device of the type mentioned at the outset in that the capacitor of the voltage booster description shows, lers and the resistor contained in the other branch the gas discharge lamp dimensioned explained. It shows are and that in the resistance branch one with the
Resistor with capacitor connected in series

such a capacity is arranged that in front ^ "uuru., ™, ™ ^, _

existing burning voltage at the gas discharge 15 F i g. 2 a switching arrangement of a first illumination lamp, the capacitors form a capacitive voltage form of an ignition device after the invention divider, at whose tap the voltage
is lower than the ignition voltage of the semiconductor diode.

According to a further embodiment of the invention, a voltage divider is in the resistance branch of the voltage divider A parallel circuit formed from a capacitor and a resistor in series with the resistor

and connected to the capacitor. With this scarf - - _o . - - _ _p

It is possible to use the lighting with a power cord provided on the network side or light output of the gas discharge lamp interference capacitor,

mator needed what to achieve small dimensions is very important. The ignition device ignites the gas discharge lamp in a relatively short period of time and also has a long service life compared to decanned starting devices, because it does not contain any mechanically operated switching elements. Further advantages result from the following

1 shows a circuit arrangement of a gas discharge lamp with the basic arrangement of a Ignition device,

manure,

F i g. 3 and 4 switching arrangements of ignition devices in modified designs,

F i g. 5 diagrams with the voltage or current curve in two successive half-periods for different embodiments of the ignition device,

F i g. 6 a circuit arrangement of an ignition device

- · "· ■ 1"., Ent.

to let increase continuously from zero to the final value.

A further embodiment of the invention consists in that the connected in series with the capacitor Resistance is partially bridged by a diode, whereby it is achieved that during of the half-periods in which this diode is conductive, the moment when the thyristor is switched on in

F i g. 7 shows a circuit arrangement of a further embodiment of an ignition device and

F i g. 8 shows a diagram with the current profile for two switching elements of the switching arrangement according to FIG Fig. 7.

The in F i g. 1 includes switching arrangement shown a gas discharge lamp 1 with two filaments 2, 3, which on the one hand via a choke 4 to the terminal

ziig to the moment of switching through during the 35 men for the connection of the mains voltage and half-periods in which the diode is blocked, is laid in front of the terminals A, B of an ignition device. The series choke required for gas discharge lamps is thereby used during the
alternating half-periods in the saturation state, which leads to an increase in the preheating capacitor 7, current for the incandescent filaments. A switching arrangement of a first embodiment

In order to periodically decrease or increase - - - - - - · -> * -

To achieve ßerung the light yield, according to a further embodiment of the invention

Capacitor in the resistance branch of the span 45. _D.

voltage divider a resistor can be connected in parallel. The ignition device according to FIG. Such a measure can, for example, have advantages for value-controlled semiconductor switching element 10, for example a thyrib. disturbance between the nodes A ' and B' to-The device can be closed in a further training. The gate of this switching element is invention also modified to the effect that 50 via a semiconductor switching diode 11, such as. B. a diac, the two-way permeable thyristor
a unidirectional thyristor and
to a parallel-connected diode connected with the same forward direction as the thyristor _

is composed, with this parallel connection 55 is switched. The functions of the capacitor 8 and one from a diode with the same pass-through inductor 9, which is responsible for the principle of ignition advance as the thyristor and a capacitor formation direction are of no importance, become even more grounded Parallel circuit is connected in series. purifies.

In the last-mentioned embodiment, the ignition moment of the device can be

between the center tap of one of two partial resistances from the values selected for the switching elements 12, 13 and 14, the existing resistance and the junction point, can be determined as desired. ⁷ ^ - a resistor can be arranged between the two diodes. A device designed in this way is not only for inductive ballasts,
but also for capacitive ballasts 65
bar.

In the ignition device according to the invention, no transformer is required to generate the ignition voltage.

device 5 are connected. The switching arrangement can furthermore be connected in series with the throttle 4 Capacitor 6 and one parallel to the mains voltage

form of an ignition device according to the invention is shown in FIG. 2 shown. This igniter occurs at the Place the in F i g. 1 with 5 designated ignition device.

connected to the junction between two capacitors 12 and 14. These two capacitors form a series circuit with a resistor 13, which is connected in parallel with the semiconductor switching element 10

The moment at which the semiconductor switching element 10 is blocked again corresponds to the zero crossing of the stream, d. This means that this point in time cannot be influenced by the choice of switching elements 12, 13 and 14 will. The capacitor 14 is, as will be explained, for achieving a reliable and trouble-free ignition effect necessary. Without

this capacitor 14 tends to arrange the ignition device way on the network side. At a soldazu, even after the gas discharge lamp has already been designed, it can be ignited in the ignition device is, in each case a new ignition device 5, the choke coil 9 can be omitted. These initiate gang, which would be a great disadvantage. Embodiments of the ignition device can be used in

When the resistor 13 is used directly with the 5 gas discharge lamps shown in Capacitor 12 and the semiconductor switching diode 11 contain an inductive circuit and are capacitively connected would, the capacitor 12 would be pensored across the.

Resistor 13 is charged until the

The current voltage is the ignition voltage value of the halftone charge at a gas discharge lamp, which accordingly Conductor switching diode 11 has reached. As a result, the io of the illustration in FIG. 1 a series capacitor 6 Semiconductor switching element 10 conductive, and which contains on is shown in FIG. 3 reproduced. In the case of this ignition device, the voltage that is present falls in accordance with the guideline is with that through the resistor 13 a jump function. If the next zero and capacitor 14 formed a series circuit passage of the current that the semiconductor switching element through a capacitor 15 and a resistor ment 10 flows through, this switching element is again connected in series in 15 16 formed parallel circuit. the the blocking state passes, such a high switching elements of this design can be so-voltage caused on the gas discharge lamp, sen that an ignition process is achieved at that the lamp can ignite. Once this has been ignited, after a relatively short waiting time the det, this is how the operating voltage arises. The required emission temperature has to be pointed out to the filaments, that the moment when the semiconductor temperature is reached and the lamp lights up steadily, Switching element 10 is each conductive, one especially until the final illuminance is available. is more important because the time it takes for heating up This embodiment can, for example, be successful

of the filaments 2, 3 of the gas discharge lamp are necessarily used in those cases in which a is manoeuvrable so that it can be ignited, from direct switching on of incandescent lamps because of the da- j depends on the length of time during which the 25 associated with sudden change in light intensity j Semiconductor switching element 10 is conductive. To possibly- is undesirable. }

Allows quick and reliable ignition of the gas. There is sometimes a need for a gas discharge

Discharge lamp, it is necessary to be able to use the resultant lamp under very different conditions, which current flows through the incandescent filaments, which is, for example, greater than a predetermined lower limit value. In 30 large mains voltage fluctuations or large j consequence of the required dimensioning of the temperature differences can be attributed. In sol- \ capacitors 12 and the resistor 13 it now results that in some cases the ignition device is subject to great demands, even when the operating voltage is present. For these applications i gas discharge lamp the semiconductor switching element 10 it is important that the preheating current for the j becomes conductive again, with the result that the gas filament is sufficiently high and the ignition voltage lamp goes out again. With this in mind, which would also be subject to a correspondingly high value i, the ignition must be repeated at the correct moment. Process take place. With a practically permanently in the conductive state

With the added capacitor 14, the semiconductor switching element 10 located on is connected to the simple and reliable way the aforementioned 40 sem a voltage shape corresponding to the Darstel disadvantage avoided. The capacitors 12 and 14 are shown in FIG. 5 a arise. The preheating current is form a capacitive voltage divider, in which the then through the choke coil 4 and the resistor The size of the capacitor 12 is essentially determined by the filament of the lamp. The work Energy pulse is determined, which is the same current in each case with a 40-Wati lamp approximately Gate of the semiconductor switching element 10 are supplied 45 be 0.5 A, and with a duty cycle of the the must to this element in the conductive to semiconductor switching element 10 of a half period J stand to bring. The capacitor 14, however, is so (Fig. 5b), the effective preheating current is about j to be dimensioned that the ignition voltage of the semiconductors is 1.5 A, which is mainly due to the fact that | Switching diode 11 is written when the operating voltage is present that the choke coil 4 unilaterally into the rade is not achieved. This means that after a saturation area is shifted and as a result of this times the gas discharge lamp is ignited, the lower impedance present has a higher one Ignition device remains ineffective. Current allows. Such a situation, which is for example

The parallel to the terminals A and B in the switching arrangement according to FIG. 2 switched capacitor 8 is an interference suppression can, is represented by the diagram in FIG. 5 c Wiedergedensator, which give the interference level of the burning lamp 55. The preheating current is reduced to a minimum permissible level after every half level. Once the node is interrupted, and it is therefore understandable semiconductor switching element 10 is conductive, is that the resultant of the preheating current short-circuited in this case, capacitor 8, which will be a strong less than 0.5 Å.

Peak current can arise. To limit this, the embodiment shown in FIG. 4 of the

The peak current is in the discharge circuit of the condenser. The ignition device is designed in such a way that the preheater 8 contains a choke coil 9, which can be increased as required for the countercurrent for the filament or can also be replaced by a resistor. Compared to the switching arrangement according to FIG. 2 can, which, however, is an additional heat loss in this embodiment, if the re-connected would be, 18 was initially disregarded, the re-

To implement an embodiment of a 65, 13 was partially bridged by the diode 17 Ignition device, the specified dimensions This determines the times for the ignition of the must not exceed, it is recommended that the semiconductor switching element 10 in each half-wave suppression capacitor 8 in the indicated in Fig. 6 differently, as shown in Fig. 5d. the

Choke coil 4 is thereby "asymmetrically" loaded in such a way that it is one-sided in the saturation state is offset and allows a higher preheating current due to the lower impedance. aside from that the phase shift between current and voltage will vary due to the lower impedance. The moments in time in which the semiconductor switching element is blocked are therefore different in each half-wave move, d. This means that the ignition voltage of the lamp is shifted within the half-waves.

In this way, it is possible to realize an ignition device that is compatible with an adequate Preheating current causes an ignition voltage on the lamp that varies in width and length. Important is the attenuation difference between positive and when selecting the values of the switching elements negative halves of the sinus. This damping is caused by the resistor-capacitor combination, which is parallel to the semiconductor switching element 10 and thus parallel to the lamp. This asymmetry is also the same offers advantages for the ignition of the lamp.

By adding a resistor 18 in parallel with the capacitor 14 it is achieved that the Lamp periodically, e.g. B. every second, decreases in light intensity for a moment. The resistance 18 must have correspondingly high resistance values (over 1 megohm). This execution form is ideal for advertising objects.

In Fig. 7 shows a switching arrangement in which an "asymmetrical" connection of the choke coil 4 is provided as an alternative solution. The semiconductor switching element 10 is replaced here by the series connection of two parallel circuits, one of which consists of a semiconductor switching element 25, such as a thyristor, and a parallel-connected diode 19, the conducting direction of the diode 19 being opposite to that of the semiconductor switching element 25. The other parallel circuit is formed by a capacitor 20 and a diode 21, the direction of which is opposite to the diode 19. As in the other embodiments, the ignition device for the semiconductor switching element 25 contains the switching elements 11, 12 and 14. The resistor 13 now consists of a combination of resistors 22, 23 and 24. The resistor 22 is connected to a capacitor 14 in series switched, while the other end of the resistor 22 is connected on the one hand via the resistor 23 to the terminal B and on the other hand via the resistor 24 to the node of both parallel circuits.

If the resistor 24 is initially disregarded, the result is that an inductive one is used Ballast, so only with the choke coil 4 or with capacitive compensation by a parallel capacitor 7 the following: The capacitor 20 is first connected via the diode 19, as shown in FIG. 8 shown is charged. The semiconductor switching element 25 can now in the same way as the semiconductor switching element 10 of the switching arrangement according to FIG. 2 can be triggered. If the capacitor 20 is just discharged, so its current will be maximal. This current is then taken over by the diode 21 and is im the rest only determined by the choke coil 4 and the resistance of the incandescent filaments.

It is easy to see that this allows preheating currents to be selected between approximately 0.5 and 1.5 A. The gas discharge lamp is operated in a manner similar to that of the switching arrangement according to F i g. 2 ignited. Here, too, the difference in attenuation between the two halves of the tension is remarkable. To now this ignition device also for To make lamps that work with a compensation by a series capacitor suitable, will the resistor 24 added. The information present in the node of the two parallel circles is necessary to understand the differences in phase shift between the two fundamentally different Balance ballasts. With the correct choice of the resistors 22, 23 and 24 one is created Ignition device suitable for inductive and capacitive ballasts.

1 sheet of drawings 909530/26 '

Claims (6)

electrode via a semi-conductor diode that is permeable in two directions with a tap 1. Device for electronic ignition trode the gas discharge lamp connected in parallel by gas discharge lamps, to the electrodes of which a voltage divider is connected, one branch of which contains a parallel resistor 5 which is permeable in two directions and the other branch of which is arranged a thyristor whose control electrode consists of a capacitor and on which With a half-handle that is permeable in two directions when the gas discharge lamp is lit, the chip conductor diode with a tap of an electrode is lower than the ignition voltage of the half-electrodes of the gas discharge lamp in parallel. A device of the type mentioned above is branch containing a resistor and the other branch consists of a capacitor in the earlier application of the German Offenlerer branch and is described in reference 1 923 872. With this ignition, its tapping when the gas discharge device is burning, the required ignition voltage is generated with the lamp, the voltage is lower than the ignition aid of a transformer, the primary voltage of which is the semiconductor diode, characterized by the coil with the two-way permeable Thyk, that the capacitor ( 12) resistor is connected in series and during each half of the voltage divider and the period in the other branch of a current for the generation of the resistance (13) in relation to the ignition pulse contained in the secondary coil, a preheating current for the filament flows through it. Such a transformer brings the gas discharge lamp dimensioned and that 20 doesn’t only involve additional expenditure, but in the resistor branch one with the resistor which makes a compact design of the (13) series-connected capacitor (14) with ignition device impossible. The maintenance of a smaller capacitance is arranged so that with dimensions it is necessary, so that the ignition existing burning voltage at the gas discharge direction in an exchangeable relatively small formation lamp the capacitors (12,14) a ca 25 housing, as it is usually for Conventional capacitive voltage divider form, at the start of which »starter« is used, can be accommodated handle the voltage is lower than the ignition voltage,
voltage of the semiconductor diode. From the German Auslegeschrift 1199 399 is 2. Apparatus according to claim 1, characterized in that a circuit arrangement for starterless ignition indicates that in the resistance branch of the 30 known from gas discharge lamps with a Voltage divider an ignition circuit oscillating from a capacitor (15) works. At this and a resistor (16) formed parallel circuit arrangement is in series with the glow electrical circuit in series with the resistor (13) and the electrode of the gas discharge lamp, a capacitor geKondensator (14) is switched. that switches the switching effect of a gas discharge 3. Apparatus according to claim 1, characterized in that the diode is intended to interrupt. For the generation of those that the resistor (13) is partially such ignition pulses, the gas discharge diode is bridged by a diode (17). switched that they under extraordinary load 4. Apparatus according to claim 3, characterized by generating tilting vibrations, the frequency of which is essential that the capacitor (14) in the borrowed is higher than the line frequency. This will Resistance branch of the voltage divider a 40 but the life of the starter and / or the gas resistor (18) is connected in parallel. discharge lamp significantly impaired. 5. Device according to one or more of the In another older application after the preceding claims, characterized by German Offenlegungsschrift 1 904 336 is a star sign, that the two-way ter for fluorescent lamps described, the particular thyristor from a unidirectional 45 more permeable for a quick start of conventional light sources Thyristor (25) and a fabric lamp connected in parallel is provided. This starter includes with the same forward direction as the thyristor one with the filaments of the fluorescent lamp in (25) connected diode (19) series-connected controlled rectifier and is set and that with this parallel connection a voltage formed from two resistors from a diode (21) with the same pass-through divider, which is parallel to the rectifier and its such as the thyristor (25) and a capacitor center tap with the control electrode of the rectifier (20) formed parallel circuit is connected in series. The rectifier is through the is tet. AC power source operated so that during the 6. Apparatus according to claim 5, characterized in that the lamp is started during one half-wave indicates that the filaments are heated between the center tap 55 of the mains voltage one consisting of two partial resistances (22, 23) and the mains voltage ends during the other half-waves Resistance (13) and the node voltage is applied to the lamp. The leading intermediate the two diodes (19, 21) a resistance of the controlled rectifier is terminated, stand (24) is arranged. after the lamp has ignited and the voltage 60 has dropped to a correspondingly lower value at the control electrode. The object of the invention is to provide a To create a device for the electronic ignition of gas discharge lamps, by means of which a gas discharge The invention relates to a device for the electric lamp after a relatively short time and ironic ignition of gas discharge lamps, which can be ignited without disruptive flashes of light, where- their electrodes parallel one in two directions for both the igniter and the permeable thyristor is arranged, the control gas discharge lamp itself an optimal life